-
684
Pelagic fi shes are not evenly dispersed in the oceans, but
aggregate at dis-tinct locations in this vast and open environment.
Nomadic species such as mackerels, tunas, and sharks form
assemblages at seamounts (Klimley and Butler, 1988; Fontenau,
1991). Fishermen have recognized this behavior and have placed
moorings with surface buoys in deep waters to provide artifi cial
landmarks, around which fi sh concentrate and are more easily
captured. These fi sh aggregating devices (termed FADs) are common
in the tropical oceans (see review, Hol-land, 1996). In a sense, it
may only be the larger size that separates a sea-mount from a
man-made FAD.
Fish may aggregate at seamounts for very different reasons. The
opportunity to feed is greater because biomass at all trophic
levels, from primary producer to apex consumer, is greater than in
the open ocean (Boehlert and Genin, 1987). The disturbance of fl ow
by the seamount creates eddies downstream that retain nutrients
critical to the growth of phytoplankton, and this enrichment
supports a greater abun-
The occurrence of yellowfi n tuna (Thunnus albacares) Thunnus
albacares) Thunnus albacaresat Espiritu Santo Seamount in the Gulf
of California
A. Peter KlimleySalvador J. JorgensenBodega Marine
LaboratoryUniversity of California, DavisWestside Road Bodega Bay,
California 94923Present address (for A. P. Klimley): Department of
Wildlife, Fish, and Conservation Biology
University of California DavisDavis, California 95616
E-mail address (for A. P. Klimley): [email protected].
Arturo Muhlia-MeloCentro de Investigaciones Biologicas del Baja
NorteApartado Postal 128La Paz, Mexico
Sallie C. BeaversBodega Marine LaboratoryUniversity of
California, DavisWestside RoadBodega Bay, California 94923
Manuscript approved for publication 30 January 2003 by Scientifi
c Editor.Manuscript received 4 April. 2003 at NMFS Scientifi c
Publications Offi ce.Fish. Bull. 101:684–692 (2003).
dance of consumers from zooplankton to apex predators. The
dipole nature of seamount magnetic fi elds and the out-ward
radiating valleys and ridges of magnetic minimums and maximums
might provide landmarks in oceanic landscape that fi sh use as a
reference to guide migration (see discussion of mag-netic
“topotaxis” in Klimley, 1993). Yel-lowfi n (Thunnus albacares) and
bigeye (Thunnus obesus) tunas do not reside long at the Cross
Seamount near Ha-waii, an observation inconsistent with the theory
that tunas feed on prey that remain aggregated at the site; rather
their rapid passage suggests that the site is a landmark used to
guide migra-tions (Holland et al., 1999). Adult yel-lowfi n tuna
also stay briefl y (
-
685NOTE Klimley et al.: Occurrence of Thunnus albacares in the
Gulf of California
Figure 1Bathymetric contour map of seamount Espiritu Santo (ES).
The circles with cross-hatching indicate the range of the
tag-detecting monitor from the sea-mount. The insert shows the
geographic location of the seamount (ES) in the Gulf of
California.
We determined the maximum range of signal-detection of one
monitor by lowering a transmitter to 10 m under a small boat and
lowering the monitor to a similar depth under a larger support
vessel. We recorded the separation distance between the two boats
using radar because the small boat and transmitter drifted away
from the support vessel that was anchored in place at the highest
point on the seamount. The VR01 monitor (Vemco Ltd., Shad Bay, Nova
Scotia, Canada) detected tags at a distance of 150 m in seas with
waves 15 and ≤25 kg) were weighed in the net and the net’s mass
subtracted from the cumulative value; and the masses of largest
tuna (>25 kg) were estimated on the basis of their length by
using the re-gression equation, y=0.216x=0.216x=0.216 + 2.981 given
in Moore (1951). The tags were inserted into the peritoneum of the
tuna while salt water was fl ushed over their gills by using the
technique described in Klimley and Holloway (1999). The tuna were
retained on board for tag implantation less than a minute.
The transmitters (Vemco Ltd., V16-6L) were cylindrical and had a
diameter of 16 mm, length of 106 mm, and net mass in water of 16 g.
They emitted individually coded tone bursts of 70 kHz separated by
60–90 s intervals. The amplitude of the pulses was 147 dB (re: 1
μP) at a distance μP) at a distance μof 1 m. The theoretical
operating life of a transmitter was 476 days. Each tag was
distinguished on the basis of a unique pulse burst by an automated
tag-detecting moni-tor attached to the ESS and ESN detection
stations. Water
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686 Fishery Bulletin 101(3)
Table 1Length and mass of the 23 yellowfi n tuna (Thunnus
albacares) tagged in the present study and the date and time of
tagging. “N” indicates tagging near northern monitor; “S” denotes
tagging near southern monitor. An asterisk in front of a
measurement indi-cates that the value is derived from the
mathematical relationship between mass and length given in Moore
(1951); “TL” denotes total length.
Tuna Time TL Mass Siteno. Date (h) (cm) (kg) (N/S)
1 11 Apr 1998 13:04 80.0 7.3 S 2 11 Apr 1998 13:21 96.0 10.8 S 3
12 Apr 1998 08:46 91.0 10.3 S 4 12 Apr 1998 08:51 106.0 13.8 S 5 12
Apr 1998 09:54 104.0 15.5 S 6 17 Jun 1998 09:54 91.5 17.0 S 7 24
Jun 1998 10:38 86.5 11.3 S 8 26 Aug 1998 10:05 138.0 *51.7 N 9 26
Aug 1998 10:45 58.0 4.5 N10 26 Aug 1998 11:43 66.0 5.5 N11 26 Aug
1998 12:16 76.0 7.0 N12 26 Aug 1998 10:14 155.0 *73.1 N13 28 Aug
1998 10:50 71.0 7.2 N14 28 Aug 1998 11:25 155.0 *73.1 N15 10 Sep
1998 17:44 149.9 *66.2 S16 10 Sep 1998 18:32 91.5 18.50 S17 10 Sep
1998 18:44 *75.0 8.50 S18 10 Sep 1998 19:07 111.8 *27.6 S19 11 Sep
1998 17:25 114.5 20.5 N20 11 Sep 1998 17:51 71.0 7.00 N21 11 Sep
1998 18:25 106.5 20.5 N22 12 Sep 1998 6:41 104.5 23.0 N23 12 Sep
1998 7:30 141.0 *55.1 N
temperature was recorded every half hour at the seamount by a
Stoaway Tidbit temperature logger (Onset Computers Corp.,
Pocassett, MA) attached to the mooring line adjacent to the
tag-detecting monitor. We calculated a daily tem-perature by
averaging the half-hourly temperatures.
We used log-survivorship analysis (Fager and Young, 1978) to
ascertain whether the tunas returned to the moni-toring stations
after favored time periods. A frequency his-togram of the time
intervals between randomly occurring point events in a Poisson
process is described by a negative exponential distribution. A
log-survivor plot of these inter-vals generates a straight line
with a slope proportional to the probability of an event occurring
at a given time after the preceding event. This analysis is used to
identify inter-vals between events that occur more frequently than
ex-pected by chance because infl ections in the resulting curve are
more easily distinguished from a straight line than the shape of
the distribution on a frequency histogram with a negative
exponential distribution. An infl ection in the log-survivor curve
indicates a change in the probability of an event occurring at a
given time after the last event—in our case the time between
successive arrivals of tunas within the ranges of the two
monitors.
Results
Twenty-three yellowfi n tunas were tagged from 11 April 1998 to
12 September 1998 (Table 1). Individuals were tagged during
daylight hours from 6:41 to 19:07 hours. The tunas ranged in length
from 71.0 to 155.0 cm TL. They ranged in mass from 7.25 to 73.1 kg.
There appeared to be two discrete size classes, small individuals
varying from 7.25 to 23.0 kg and large ones from 51.7 to 73.1 kg.
The masses of the larger individuals were determined from their
lengths by using a regression equation (Moore, 1951).
The yellowfi n tunas stayed at seamount Espiritu Santo over
varying time periods (Fig. 2). Nine of the 23 tunas left the
seamount on the same day that they were tagged (Fig. 2A). Two of
the nine returned to the seamount once for a single day, one within
a week of tagging and the other after two and one-half months. Six
tunas stayed intermediate periods of time after tagging, ranging
from two to six weeks. One of these tunas (no. 9) was eventually
caught at the seamount. Another tuna (no.10) visited for a single
day after an absence of fi ve weeks and returned again after a
similar period to stay for 15 months. Four
-
687NOTE Klimley et al.: Occurrence of Thunnus albacares in the
Gulf of California
Tem
p. (
cels
ius)
Tagg
ed in
divi
dual
sTa
gged
indi
vidu
als
Tem
p. (
cels
ius)
Tagg
ed in
divi
dual
sTa
gged
indi
vidu
als
Tem
p. (
cels
ius)
Tem
p. (
cels
ius)
Tagg
ed in
divi
dual
sTa
gged
indi
vidu
als
Figure 2Chronology of daily visits by 23 tagged yellowfi n tuna
to the seamount and temperature record over a 30-month period
beginning April 1998 and ending October 2000. Each visit, indicated
by a solid diamond, is based on the detection of a tag during a
24-h period by either the north (ESN) or south (ESS) monitoring
stations. The lines in the graphs show that the ultrasonic tag had
yet to be recovered from a yellowfi n tuna. T = day of tagging, C =
day of capture, and F = date of shedding of tag.
Month of year
AAA
BB
CC
individuals (nos. 5, 19, 21, and 23) stayed for longer peri-ods
of time, ranging from six to 18 months. One of these tunas (no. 5)
was also caught by a fi sherman. It is likely
that some tunas are nomadic and stay only a single day, whereas
others are resident, remaining at the seamount throughout the
year.
-
688 Fishery Bulletin 101(3)
It is unlikely that the tags on the two tunas (nos. 10 and 23),
which stayed at the seamount longest, were shed and lay on the
bottom. The reasons supporting their being attached to living tunas
are as follows. First, the two tags were not recorded with equal
frequency during all times of the day as might be expected of a tag
lying at one location within the range of the monitors. The tags
were usually de-tected for a few hours and then absent for a
similar period. This pattern of detection is consistent with the
tunas mov-ing within the range of the monitor and later outside its
range. Second, the two tags were jointly detected after long
periods of absence or ceased being detected simultaneously after
long periods of presence. This reception pattern is consistent with
the two tunas moving in and out of the de-tection range of the
monitors within the same school. Third, one tuna (no. 23) was
detected by the monitor on the south side of the seamount, but not
on the north side during one day; the same tuna was detected by the
northern monitor, but not the southern monitor on the next day.
This pattern of detection was consistent with the tuna swimming
over the northern region of the seamount on the fi rst day and over
the southern region on the second day.
The yellowfi n tunas were present at the seamount at all seasons
of the year. Five of the tunas tagged during August and September
1998 (nos. 7, 8, 9, 16, and 17) emi-grated during early fall as the
water temperature began to decrease (Fig. 2A). However, three
individuals (nos. 10, 21, and 23) remained at the seamount from
January 1999 to April 1999 when the temperature dropped to 18°C.
Two (nos. 10 and 23) remained present when the subsurface water
temperature descended to 16°C during the following winter of 2000
(Fig. 2B).
The yellowfi n tunas remained at the seamount at all times of
the day. This is evident from a 24-h record of the arrivals of 10
tunas during a 15-d period from 16 to 30 September 1998 (Fig. 3).
The tunas were present more often during daytime, from 06:00 to
18:00 hours, during the fi rst 12 days. Notice the clustering of
the different symbols in Figure 3, each indicating a specifi c
tuna, in separate columns during the period from 06:00 to 18:00
hours. However, the amount of time spent at the sea-mount became
more evenly distributed between daytime and nighttime by 28
September. Note the even dispersion of the symbols over the 24-h
period during the last three days of the 15-day period. There was
little variation evi-dent in the frequency of arrivals at different
times of the day when the arrivals were summed over the entire
study (Fig. 4). The percentage of arrivals during each hour of the
day (see crosshatched polygon) differed little from an even
distribution of arrivals (4.2%/h) throughout the day (see dashed
circle).
We determined the frequency of various lengths of stays at the
north (Fig. 5A) and south sites (Fig. 5B) at the Espiritu Santo
Seamount. A stay for a particular tuna was defi ned as the period
of detections with no separation intervals greater than 15 min. Let
us say that tuna 1 was detected at 08:00, 08:14, 08:28, and 09:00
hours. The dura-tion of the stay of tuna 1 would be 28 min. The
second detec-tion followed the fi rst by 14 min (
-
689NOTE Klimley et al.: Occurrence of Thunnus albacares in the
Gulf of California
Figure 3Twenty-four hour chronology of visits by 10 tagged tuna
to the monitoring station ESN during 15 days from 16 to 30
September 1998. A unique symbol indicates the presence of a
particular individual within the range of the monitor during a
15-min position. Note the predominance of daytime visits during the
fi rst nine 24-h periods and then a progressive shift to an equal
number of visits during daytime and nighttime (see 28−30 Sept.
1998).
Arr
ival
tim
es (
hrs)
Tuna repeatedly moved in and out of the monitor range over many
days or left for the duration of the study. Sixty percent of all
absences at ESN and 65 % of the absences from ESS were for less
than 1 hour. If these tunas were to swim at a sustained rate of 0.5
m/s (see Magnuson, 1978), they would not move more than 900 m out
the reception range of the monitors (60 min × 60 s × 0.5 m/s /2).
This close attachment to the seamount contrasts with the behavior
of tuna at FADs offshore of Hawaii. Tunas visited the FADs there
rarely and spent little time within the range of the monitor before
departing for a period of several weeks (Klimley and Holloway,
1999). The present study suggests that the Espiritu Santo Seamount
is a substantial feeding ground that can support a year-round
resident population of yellowfi n tunas. However, other tunas may
stay only
briefl y at the seamount, using it as a landmark, before
continuing on their nomadic migrations.
Seamounts have dipole magnetic fi elds associated with them
because of the antiparallel polarity of magnetite within volcanic
magma extruded during periods when the earth’s polarity was
reversed (Parker et al., 1987). Furthermore, maxima (ridges) and
minima (valleys) in the magnetic fi eld often lead outward from
seamounts due to the extrusion of magma. Klimley (1993) proposed
that hammerhead sharks use these for guidance during their
nocturnal migrations into the surrounding water to forage. This
physical property of the sea fl oor, originating far below where
the fi shes swim, could provide a fi xed reference (or waypoint)
for yellowfi n during their migrations. This species of tuna has
been shown to sense distinct patterns in a magnetic fi eld (Walker,
1984).
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690 Fishery Bulletin 101(3)
Conclusions
Twenty-three yellowfin tuna were tagged with coded ultrasonic
beacons during a fi ve-month period between 11 April and 12
September 1998. These tunas were cap-tured, tagged, and
released
-
691NOTE Klimley et al.: Occurrence of Thunnus albacares in the
Gulf of California
Per
cent
age
of in
terv
als
> t
Interval t between visits (hrs)
Figure 6Log-survivor plots of percentages of intervals between
successive tuna arrivals greater than time t over 24-h periods at
monitoring stations ESN (A) and ESS (B).
Figure 7Percentages of visits of greater than one day made by
tuna to two monitoring stations with single day intervals ranging
from 2–9 days and 10-day inter-vals ranging from 10–19 to 90–99
days.
Interval between visits (days)
Per
cent
tota
l
AA
B
may use the site either as a landmark during their migra-tory
transit or as a feeding destination as suggested by the short and
long periods of time spent at the seamount.
Acknowledgments
We would like to thank those on the staff of Centro de
Inves-tigaciones Biologicas del Baja Norte of La Paz, Mexico, who
helped us tag yellowfi n tuna at seamount Espiritu Santo. This work
was funded by the Biological Oceanography Program of the National
Science Foundation (grant: OCE-9802058) and CONACYT of Mexico
(grant: PN-9509-1995 and PN-1297-1998).
Literature cited
Boehlert, G. W., and A. Genin.1987. A review of the effects of
seamounts on biologi-
cal processes. In Seamounts, islands, and atolls (B. H. Keating,
P. Fryer, R. Batiza, and G. W. Boehlert, eds.), p. 319–334.
Geophys. Monogr. Ser. 43.
Fagan, R. M., and D. Y. Young.1978. Temporal patterns of
behavior: durations, intervals,
latencies, and sequences. In Quantitative ethology (P. W.
Colgan, ed), p.78–114. John Wiley & Sons, New York, NY.
Fonteneau, A.1991. Seamounts and tuna in the tropical Atlantic.
Aquat.
Living Resour. 4:13–25.Holland, K. N.
1996. Biological aspects of the association of tunas with FADs.
SPC Fish Aggregating Device Information Bull. 2:2–7.
Holland, K. N., P. Kleiber, S. M. Kajiura.1999. Different
residence times of yellowfi n tuna, Thun-
nus albacares, and bigeye tuna, T. obsesus, found in mixed
aggregations over a seamount. Fish. Bull., 97:392–395.
Klimley, A. P.1993. Highly directional swimming by scalloped
hammer-
head sharks, Sphyrna lewini, and subsurface irradiance,
temperature, bathymetry, and geomagnetic fi eld. Mar. Biol.
117:1–22.
1985. Schooling in the large predator, Sphyrna lewini, a species
with low risk of predation: a non-egalitarian state. Ethology,
70:297−319.
Klimley, A. P., and S. B. Butler.1988. Immigration and
emigration of a pelagic fi sh assem-
blage to seamounts in the Gulf of California related to water
mass movements using satellite imagery. Mar. Ecol. Progr. Ser.
49:11–20.
Klimley, A. P., and C. Holloway.1999. Homing synchronicity and
schooling fi delity by yel-
lowfi n tuna. Mar. Biol. 133: 307–317.Magnuson, J. J.
1978. Locomotion by scombrid fi shes: hydrodynamics,
mor-phology, and behavior. Fish Physiol. 239– 313.
Parker, R. L., L. Shure, and J. A. Hildebrand.1987. The
application of inverse theory to seamount
magnetism. Rev. Geophys. 25:1−65.
-
692 Fishery Bulletin 101(3)
Moore, H. L.1951. Estimation of age and growth of yellowfi n
tuna (Neo -
thunnus macropterus) in Hawaiian waters by size fre-quencies.
Fish. Bull. 52:131–149.
Walker, M. M.1984. Learned magnetic field discrimination in
yellow-
fi n tuna, Thunnus albacares. J. Comp. Physiol 155:673–679.